Apparatus for transforming image data for another and method

ABSTRACT

A method of transforming an image format of image data stored in an apparatus connected via a network is disclosed. The method includes the steps of providing the apparatus with format information containing image formats of image data that can be transformed, receiving a request for transforming the image format of the image data from the apparatus, acquiring the image data from the apparatus, transforming the image format of the image data acquired from the apparatus thereby to form format-transformed image data, and providing the format-transformed image data to the apparatus. According to the above arrangements, an image transforming apparatus using the method can transform the image format of the image data on behalf of the apparatus.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to an image transformationapparatus, and more particularly, to an image transformation apparatusthat transforms image data for another apparatus connected via anetwork, and a method of transforming the image data.

2. Description of the Related Art

There are many formats of image data. For example, JPEG is one of themost common formats of image data used for personal computers. MH, MR,and MMR are generally used for facsimile machines. Each format isdesigned for a specific purpose of use and an environment.

It is often necessary to transform image data of a format into imagedata of another format. For example, when JPEG image data are to betransmitted via facsimile, the JPEG image data need to be transformedinto MH, MR, or MMR.

In such a case, a user may use various apparatuses such as a personalcomputer in which a computer program for transforming image data formatis installed, and a multifunction peripheral that functions as a copierand a scanner, for example, as well as a facsimile, depending on theoccasion.

However, even image data can be easily transmitted via a network becauseof the improvements in network technology. If an apparatus can requestanother apparatus connected via a network to transform image data on itsbehalf, the apparatus does not need to have a transformation unit fortransforming image data. If the apparatus has its own transformationunit for transforming image data, but the other apparatus has atransformation unit of a higher performance level, the apparatus may beable to transform the image data at a higher efficiency by requestingthe other apparatus to transform the image data.

SUMMARY OF THE INVENTION

Accordingly, it is a general object of the present invention to providea novel and useful image transformation apparatus in which at least oneof the above problems is eliminated.

Another and more specific object of the present invention is to providean image transformation apparatus that transforms image data for anotherapparatus connected via a network, and a method of transforming imagedata for another apparatus.

To achieve at least one of the above objects, the method according tothe present invention is capable of transforming an image format ofimage data stored in an apparatus connected via a network, the methodincluding the steps of:

providing the apparatus with format information containing image formatsof image data that can be transformed;

receiving a request for transforming the image format of the image datafrom the apparatus;

acquiring the image data from the apparatus;

transforming the image format of the image data acquired from theapparatus thereby to form format-transformed image data; and

providing the format-transformed image data to the apparatus.

According to the above arrangements, if the apparatus is not capable oftransforming the image format of the image data, or the capability ofthe apparatus is inferior to that of the image transforming apparatus,the image transforming apparatus, using the method, can transform theimage format of the image data in response to a request from theapparatus.

Other objects, features, and advantages of the present invention willbecome more apparent from the following detailed description when readin conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a network diagram for explaining a system according to anembodiment;

FIG. 2 is a block diagram showing a multifunction peripheral accordingto an embodiment;

FIG. 3 is a hardware diagram showing the multifunction peripheral shownin FIG. 2;

FIG. 4 is a schematic diagram for explaining the flow of image data andrelated configuration according to an embodiment;

FIG. 5 is a sequence diagram for explaining the transforming of imagedata according to an embodiment;

FIG. 6 is a flowchart for explaining the acquiring of resourceinformation according to an embodiment;

FIG. 7 is a table of exemplary resource information according to anembodiment;

FIG. 8 is an exemplary table that correlates a combination of an inputformat and an output format to a transformation type according to anembodiment;

FIG. 9 is a flowchart for explaining processing of a server thatreceives “GetMachineInfo” according to an embodiment;

FIG. 10 is a flowchart for explaining processing for generating resourceinformation (1) according to an embodiment;

FIG. 11 shows an exemplary screen for setting the MLB accessible fromother apparatuses;

FIG. 12 shows an exemplary screen for setting information of apparatusesthat are permitted to access the MLB according to an embodiment;

FIG. 13 is a flowchart for explaining step S303 of the flowchart shownin FIG. 9 according to an embodiment;

FIG. 14 is a flowchart showing the operation of the client according toan embodiment;

FIG. 15 is a flowchart for explaining an exemplary operation of a serverthat has received a request for transforming an image from a clientaccording to an embodiment;

FIG. 16 is a flowchart for explaining exemplary transformation of animage performed by the server according to an embodiment; and

FIG. 17 is a flowchart for explaining an exemplary charging process.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The preferred embodiments of the present invention are described indetail below. In the following description, image data may be referredto as an image, and the transforming of the format of image data may bereferred to as the transforming of an image. Additionally, it is assumedin the following description that an image transformation apparatus is amultifunction peripheral (MFP), which may be referred to as a “machine”.However, the image transformation apparatus is not limited to the MFP.

FIG. 1 is a network diagram for explaining the outline of the preferredembodiments. The network system shown in FIG. 1 includes MPFs 201 andanother MFP 202 in which a media link board (MLB) 203 for transformingimages is installed, connected via a network 205. The MLB 203 isgenerally built within the MFP 202. However, in FIG. 1, the MLB 203 isshown outside of the MFP 202.

As shown in FIG. 1, the MFP 202 serves the MFP 204 (one of the MFPs 201connected to the MFP 204 via the network 205) for transforming images.

According to the above arrangements, even if the MFP 204 has no built-inMLB, the MFP 204 can have images transformed by the MLB 203 of the MFP202. If the MFP 204 has a low-performance MLB (not shown), but the MLB203 of the MFP 204 is of high performance, the MFP 204 can have imagestransformed by the high-performance MLB 203 of the MFP 202.

The structure and operation of the MFP are described below. FIG. 2 is aschematic diagram showing the configuration of a MFP 1. The MFP 1includes computer programs 2 that perform the image forming, a MFPstarting unit 3, and hardware resources 4 that are used for the imageforming.

When the MFP 1 is powered on, the MFP start unit 3 is started first, andactivates an application layer 5 and a platform layer 6. The MFPstarting unit 3 reads programs of the application layer 5 and theplatform layer 6 from a hard disk drive (HDD) (not shown) and loads theprograms to a memory region (not shown), for example, and activates theprograms. The hardware resources 4 include a monochrome laser printer51, a color laser printer 52, an operations panel 53, the MLB 54, andother hardware resources 50 such as a scanner and a facsimile unit.

The software programs 2 are executed on an operating system OS such asUNIX (registered trade mark). The software programs 2 include theapplication layer 5 and the platform layer 6. The application layer 5includes programs that perform specific user services related to theimage forming such as printing, copying, facsimile, and scanning.

The application layer 5 includes a printer application 20 correspondingto printing functions, a copier application 21 corresponding to copyingfunctions, a facsimile application 22 corresponding to facsimilefunctions, and a scanner application 23 corresponding to scanningfunctions.

The platform layer 6 includes a control service layer 7, a systemresource manager (SRM) 40, and a handler layer 8. The control servicelayer 7 interprets a request for processing data from the applicationlayer 5, and issues a request for allocating the hardware resources 4.The SRM 21 manages one or more hardware resources 4 to arbitraterequests for allocating the hardware resources 4 from the controlservice layer 7. The handler layer 8 handles the hardware resources 4 inaccordance with a request for allocating the hardware resources 4 fromthe SRM 40.

The control service layer 7 includes one or more service modules suchas: a network control service (NCS) 30, a delivery control service (DCS)31, an operations panel control service (OCS) 32, a facsimile controlservice (FCS) 33, an engine control service (ECS) 34, a memory controlservice (MCS) 35, an on-demand update service (OUS) 36, a userinformation control service (UCS) 37, and a system control service (SCS)38.

The platform layer 6 is configured to include an application programinterface (API) 43 through which the application layer 5 sendsprocessing requests to the platform layer 6 by issuing a function call.Programs of the application layer 5 and the platform layer 6 may besimultaneously executed on an operating system (OS) as processes.

The process of the NCS 30 provides a common service available for allapplication programs that require network interface. The process of theNCS 30 receives data from another resource connected to the network inaccordance with various protocols, and transfers the received data to adesignated application program, and vice versa.

The NCS 30 communicates with another network apparatus via the networkusing a HyperText Transfer Protocol Daemon (httpd) in accordance withthe HyperText Transfer Protocol (HTTP).

The process of the DSC 31 controls the distribution of documents storedin the MFP 1. The process of the OCS 32 controls an operations panelthrough which a user (or a service person who maintain the MFP 1) andthe system of the MFP 1 communicate.

The process of the FCS 33 provides the application layer 5 with theapplication program interface (API) 43 through which the applicationlayer 5 can exchange facsimile messages via PSTN and/or ISDN. Theapplication layer 5 can further register and retrieve facsimile messagesstored and managed in a backup memory (not shown) through the API 43.The application layer 5 can read and print the facsimile messagesthrough the API.

The process of the ECS 34 controls engines such as those of themonochrome laser printer 51, the color laser printer 52, and the otherhardware resources 50. The process of the MCS 35 manages memory(storage) such as the HDD by reserving and/or discharging a memoryregion. The process of the OUS 36 downloads programs via the network,and stores the downloaded programs in the memory.

The process of the SCS 38 manages the application programs, controls theoperations unit, displays system screens, indicates information viaLEDs, manages the hardware resources, and controls interruption ofapplications, for example.

The process of the SRM 40 controls the system of the MFP 1 and managesthe hardware resources 4 in cooperation with the SCS 38. The process ofthe SRM 40 arbitrates requests for allocating the hardware resources 4from the upper rank layer thereby to control the use of the hardwareresources 4. The process of the SRM 40 schedules the use of the hardwareresources 4 in response to a request from the upper rank layer. Forexample, the process of the SRM 40 directly controls papertransportation and image forming of the printer engines, memoryreservation, and file creation.

The handler layer 8 includes a facsimile control unit handler (FCUH) 41,an image memory handler (IMH) 42, and a MEU 45. As will be appreciated,the FCUH 41 controls a facsimile control unit (FCU) 68 (see FIG. 3). TheIMH 42 allocates memory regions to processes, and manages the allocatedmemory regions. The MEU 45 gives the MLB 54 instructions fortransforming images.

The SRM 40 and FCUH 41 give the hardware resources 4 requests forprocessing through an engine interface (I/F) 44 by using a predeterminedfunction.

As described above, the MFP 1 can centrally perform processing commonlyrequired by the applications of application layer 5. The hardwarestructure of the MFP 1 is described next.

FIG. 3 is a schematic diagram showing the hardware structure of the MFP1 according to an embodiment. The MFP 1 includes a controller board 60,an operations panel 53, the FCU 68, an engine 71, and a plotter 72. TheFCU 68 includes a G3 unit 69 and a G4 unit 70.

The controller board 60 includes the following: a CPU 61, an ASIC 66, aHDD 65, a local memory (MEM-C) 64, a system memory (MEM-P) 63, a northbridge (NB) 62, a south bridge (SB) 73, a network interface card (NIC)74, a USB device 75, an IEEE 1394 device 76, and a Centronics device 77.

The operations panel 53 is connected to the ASIC 66 mounted on thecontroller board 60. The following are connected to the NB 62 via a PCIbus: the SB 73, the NIC 74, the USB device 75, the IEEE 1394 device 76,the Centronics device 77, and the MLB 54. The MLB 54 is connected to theimage transformation apparatus (MFP 1) via the PCI bus. The image dataare provided from the MFP 1 to the MLB 54, are transformed by the MLB54, and returned from the MBL 54 to the MFP 1.

The FCU 68, the engine 71, and the plotter 72 are connected to the ASIC66 of the controller board 60 via the PCI bus.

On the controller board 60, the local memory 64 and HDD 65 are connectedto the ASIC 66, and the CPU 61 and ASIC 66 are connected to each othervia the NB 62 (a CPU chip set). Even if the interface of the CPU 61 isnot known, the ASIC 66 can be connected to the CPU 61 via the NB 62.

The ASIC 66 and the NB 62 are connected via an accelerated graphics port(AGP) 67, instead of the PCI bus. The reason why the ASIC 66 and the NB62 are connected to each other via the AGP 67, which is faster than thePCI bus, is that multiple processes of the application layer 5 and theplatform layer 6 need to be executed concurrently without degrading theperformance of the system.

The CPU 61 controls the entire system of the MFP 1. The CPU 61 executesthe following programs on the operating system as processes: the NCS 30,DCS 31, OCS 32, FCS 33, ECS 34, MCS 35, OUS 36, UCS 37, SCS 38, SRM 40,FCUH 41, and the IMH 42. The CPU 61 further executes the printerapplication 20, the copier application 21, the facsimile application 22,and the scanner application 23.

The NB 62 is a bridge device that connects the CPU 61 with the systemmemory 63, the SB 73 and the ASIC 66. The system memory 63 is the memoryfor storing image data for image forming of the MFP 1. The SB 73 is abridge device that connects the NB 62, through the PCI bus, with andother peripheral devices. The local memory 64 is the memory forbuffering copier image data and codes.

The ASIC 66 is an application specific integrated circuit that includeshardware elements for image processing. The HDD 65 is a storage devicefor storing images, documents, computer programs, fonts, and forms, forexample. The operations panel 53 accepts instructions input by the user,and displays information for the user.

The flow of image data in the MFP 1 and the configuration of the MFP 1related to the flow of the image data are described below. FIG. 4 is aschematic diagram showing the configuration of the MFP 1 including aninput unit 47, a memory 46, the MLB 54, the HDD 65, an output unit 48, aplotter 72, and an external interface (I/F) 55.

The input unit 47 operates to input images used for copying, printing,facsimile, and scanning. The memory 46 stores the images input throughthe input unit 47 and images received through the external I/F 55.Either the system memory (MEM-P) 63 or the local memory (MEM-C) 64 mayoperate as the memory 46. The HDD 65 also stores the input imagesthrough the input unit 47 and the external I/F 55.

The MLB 54 transforms the format of images stored in the memory 46 orthe HDD 65. The plotter 72 prints the images provided by the output unit48. The external I/F 55 connects the MFP to the network.

As shown in FIG. 4, the images input through the input unit 47 or theexternal I/F 52 are directly stored in the HDD 65, or stored in the HDD65 after being transformed by the MLB 54.

A description of the formats of images that are input to the input unit47 is given below. The formats of images that are input through theinput unit 47 include binary, 4-leveled, 8-leveled, MH/MR/MMR, JPEG,RGB, and NFC1, for example. NFC1 is one of plural compression formats.

The MLB 54 can transform images of the following formats: binary,4-leveled, 8-leveled, MH/MR/MMR, JPEG/JPEG 2000, RGB/sRGB, NFC1, andTIFF, for example. The transformation is performed by MLB 54 that is ahardware device for transforming images at high speed.

The HDD 65 can store images of the following formats: binary, 4-level,8-level, multi-level, MH/MR/MMR, JPEG, RGB, NFC1, K4, K8, TIFF, and RGB,for example. K4 and K8 are formats for compressed images.

The plotter 72 can accept images of the following formats: binary,4-level, 8-level, and NFC1.

The external I/F 55 can exchange images of the following formats:binary, 4-level, 8-level, MH/MR/MMR, JPEG, and NFC1.

In the description of the embodiments, it is assumed that the changingof magnification of an image is a part of the transformation of theimage. The changing of magnification of an image means the changing ofimage size, for example, from A4 size to A3 size.

FIG. 5 is a sequence chart showing a series of steps performed by theMFP 202 (hereinafter referred to as a server 301) that providestransformation service and the MFP 204 (hereinafter referred to as aclient 302) that receives the transformation service from the server301.

In step S101, when the server 301 is activated, the client 302 detectsthat the server 301 has been activated, and then, transmits a request“GetMachineInfo” to the server 301 for acquiring resource information ofthe server 301. The resource information is information related to thetransforming of images of the server 301.

The client 302 also transmits information such as an IP address, adepartment code, a manufacturer code, and a password with the request.In the case of a corporate user, the department code may be used formanaging the client by the department of the corporation. According toan embodiment, if the server 301 and the client 302 belong to differentdepartments, a request from the client 302 for accessing the server 301may be rejected. The password is used for authenticating the client 302.

In step S102, the server 301 transmits the resource information using“MachineInfoRes” in response to receipt of the request “GetMachineInfo”.The server 301 transmits a department code, a manufacturer code, imagetransformation speed, transformable magnification range, andtransformable image types to the client 302. For example, the imagetransformation speed may be represented in units of MB/sec. Thetransformable magnification range indicates the range of magnificationsin which an image can be expanded or reduced. The transformable types isinformation indicating that, for example, a format A can be transformedinto a format B, but cannot be transformed into a format C.

In step S103, when the client 302 requires an image to be transformed,the client 302 transmits a request “ImageTransReq” to the server 301 fortransforming the image. The client 302 also transmits the IP address,the department code, the manufacturer code, and the password thereof.

In step S104, in response to receipt of the request, the server 301returns a response using “ImageTransRes” to the client 302, the responseindicating whether the request is “accepted” or “rejected”, and furtherindicating, if the request is “accepted”, a URL in which the image to betransformed is to be stored.

If the request is accepted, the client 302 transmits the image to thedesignated URL and requests the server 301 to start transforming theimage using “TransStartReq” in step S105.

The server 301 transforms the format of the image, and in step S106,returns the result of the transformation using “ImageTransEnd” to theclient 302. The transformation result indicates either normal completionor abnormal ending. If the transformation result is normal completion, aURL at which the transformed image is placed is designated. The client302 can acquire the transformed image from the designated URL.

In step S107, the server 301 charges the client 302 for the use of MLBusing “ChargeReq”. According to an embodiment, the charged amount maychange transformation by transformation. The charge may be accumulatedusing a counter provided to the client 302.

Processing performed by the client and the server is described below.FIG. 6 is a flowchart showing steps of the client 302.

In step S201, the client 302 determines whether a new machine isdetected, and repeats this step until a new machine is detected. In stepS202, when a new machine is detected, the client 302 transmits therequest “GetMachineInfo” to the detected machine. In step S203, theclient 302 waits for a response from the detected machine. In responseto receipt of the response from the detected machine, the client 302registers the resource information transmitted from the detected machinein step S204.

As described above with reference to FIG. 5, the resource informationcontains the image transformation speed, the transformable magnificationrange, and the transformable types. FIG. 7 shows the structure ofexemplary resource information. As shown in FIG. 7, the resourceinformation includes the image transformation speed 101, thetransformable magnification range 102, and the transformable types 103.The image transformation speed 101 is represented as “AA MB/s”. Theminimum value of the transformable magnification and the maximum valueof the transformable magnification are indicated as MIN %-MAX %,respectively.

The transformable type 103 indicates using “O” or “X” whether a formatcan be transformed into another format. Specifically, FIG. 7 shows thatthe type 1 is transformable but type 2 is not.

A type is defined by designating an input format and an output format asshown in FIG. 8. FIG. 8 is an exemplary table that defines the types.For example, the type 7 corresponds to a combination of format A as theinput format and format C as the output format. The combination of theformat C as the input format and format D as the output formatcorresponds to type 12.

The client 302 retains the resource information acquired from the server301. It is assumed in the present embodiment that only one server 301exists in the network. According to another embodiment, multiple serversin each of which a MLB 54 is installed may exist in a network. In such acase, the client 302 may retain resource information of each server 301.

FIG. 9 is a flowchart showing the operation of the server 301 that hasreceived a request “GetMachineInfo” from a client 302.

In step S301, the server 301 determines whether a request“GetMachineInfo” has been received, and repeats this step until thedetermination turns to YES.

In response to receipt of the request “GetMachineInfo”, in step S302 theserver 301 determines whether the server itself makes the MLB 54installed therein accessible (GENERATING RESOURCE INFORMATION (1)). Thisstep is described in further detail below. In step S303, the server 301makes performance information of the MLB 54 installed therein accessible(GENERATING RESOURCE INFORMATION (2)). This step is described in furtherdetail below.

In step S304 subsequent to step S303, the server 301 transmits theresource information to the client using “MachineInfoRes”. The server301 waits until the resource information is transmitted by repeatingstep S305. If the server 301 determines that the resource informationhas been transmitted, the process returns to step S301.

FIG. 10 is a flowchart for explaining the above step S302 in moredetail. In step S401, the server 301 determines whether a MLB 54 isinstalled therein. If a MLB 54 is not installed therein, the processproceeds to step S407. In step S407, a determination is made that theMLB 54 is not accessible from other apparatuses, and then, the processends. If a MLB 54 is installed therein (S401 YES), the process proceedsto step S402.

In step S402, the server 301 determines whether the MLB 54 installedtherein is normally operable. If the MLB 54 is not normally operable,the process proceeds to step S407 because it makes no sense to make theMLB 54 accessible from the other apparatuses. If the MLB 54 is normallyoperable, the process proceeds to step S403.

In step S403, the server 301 determines whether it is permitted to makethe MLB 54 accessible. If it is not permitted to make the MLB 54accessible from other apparatuses, the process proceeds to step S407. Ifit is permitted to make the MLB 54 accessible from other apparatuses,the process proceeds to step S404. According to an embodiment, thepermission may be set by a Serviceperson Program (SP).

As described above with reference to FIG. 2, the MLB 54 is connected toother components of the MFP 202 through the PCI bus. If the MLB 54 ismade accessible from other apparatuses, the additional accesses (besidesaccesses from the MFP 202 in which the MLB 54 is installed) maysignificantly increase traffic on the PCI bus, and consequently degradethe performance of the MFP 202. In such a case, it may be appropriate todetermine that the MLB 54 is not accessible from other apparatuses.

In step S404, the server 301 determines whether the requesting client302 is authorized to access the MLB 54. If the client 302 is notauthorized, the process proceeds to step S407. If the client 302 isauthorized to access the MLB 54, the process proceeds to step S405.According to an embodiment, the determination may be made by determiningwhether the client 302 has an operating license for the MLB 54, forexample. If the access to the MLB 54 is restricted to clients 302 of aparticular department of a firm, accesses from clients 302 belonging todifferent departments are not authorized.

If the server 301 (MFP 202) requires a password, the server 301determines whether the password transmitted from the client matches instep S405. If the password does not match, the process proceeds to stepS407. If the password matches, the process proceeds to step S406. Instep S406, the server 301 determines that the MLB 54 is accessible fromother apparatuses, and then, the process ends.

A description about the Serviceperson Program is given below. FIG. 11 isan exemplary screen 104 for setting the MLB 54 accessible from otherapparatuses. Two buttons 105 and 106 indicating NO and YES,respectively, are provided in the screen 104. The screen 104 may bedisplayed on the operations panel 53, for example.

A service person or a user can set the MLB 54 accessible or inaccessibleby pressing the buttons 106 and 105, respectively, in the screen 104.

FIG. 12 is a screen 107 for setting information of machines(apparatuses) that are permitted to access the MLB 54. Boxes 108 inwhich IP addresses are input are provided in the screen 107. The serviceperson or the user can designate the machines that are permitted toaccess the MLB 54 by inputting the IP addresses of the machines(apparatuses) in the boxes 108.

FIG. 13 is a flowchart for explaining step S303 of the flowchart shownin FIG. 9 in more detail. In step S501, the server 301 acquires theperformance of the MLB 54 installed therein. For example, theperformance of the MLB 54 is assumed as follows:

IMAGE TRANSFORMATION SPEED=10 (MB/s)

MAGNIFICATION RANGE=20%-400%

TRANSFORMABLE FORMATS=1, 2, 3, 4, 5, 6, 7, 8, 9, 10.

In step S502, the server 301 determines whether the requesting client302 is in the same group (department, for example). The determination ismade for discriminating the quality of service provided to the samegroup clients 302 from that provided to different group clients 302.

If the requesting client 302 is in the same group, the server 301 setsup the resource information in step 503. For example, the resourceinformation is assumed as follows:

IMAGE TRANSFORMATION SPEED=10 (MB/s)

MAGNIFICATION RANGE=20%-400%

TRANSFORMABLE FORMATS=1, 2, 3, 4, 5, 6, 7, 8, 9, 10. This means that theclient 302 of the same group can access the full performance of the MLB54.

If the requesting client 302 is not of the same group, the server 301sets up the resource information in step S504 in the same manner.However, because the requesting client 302 is not of the same group, theresource information transmitted to the requesting client 302 is assumedas follows:

For example, the performance of the MLB 54 is assumed as follows:

IMAGE TRANSFORMATION SPEED=8 (MB/s)

MAGNIFICATION RANGE=60%-200%

TRANSFORMABLE FORMATS=1, 2, 3, 4, 5.

This means that the client 302 of a different group is permitted to useonly a part of the full performance of the MLB 54. According to theabove arrangements, the server 301 can give more favorable service tothe same group client 302 than it does to a different group client 302.

FIG. 14 is a flowchart showing the operation of the client 302. It isassumed in the following description that the client 302 has its own MLB54 installed therein. According to another embodiment, the client 302may have software for transforming images instead of the MLB 54.

In step S601, the client 302 acquires the performance information ofimage transforming of its own MLB 54. If the client 302 has software fortransforming images instead of a MLB 54, the client 302 may acquire theperformance information of the software. In step S602, the client 302acquires the performance information of image transforming, that is, theresource information of other machines. As described above, multipleservers 301 may exist in the network. If multiple servers 301 exist inthe network, the client 302 receives resource information from eachserver 301. As a result, steps S602, S603, and S604 form a loop.

In step S603, the client 302 determines whether another machine cantransform images based on the acquired resource information from theother machine. If the other machine cannot transform images, the processproceeds to step S604, and further determines whether the resourceinformation of all machines in the network has been received. If theresource information of all machines has not yet been received, theprocess returns to step S602.

If the client 302 determines in step S604 that the resource informationof all machines has been acquired, it means that none of the detectedmachines has an image transformation function. In step S605, the clientdetermines whether a MLB 54 is installed therein.

If no MLB 54 is installed therein, the client 302 determines in stepS606 that images cannot be transformed, and the process ends. If theclient 302 determines that a MLB 54 is installed therein, the client 302transforms the image using the MLB 54 installed therein in step S609,and the process ends.

If the client 302 determines in step S603 that another machine has animage transformation function, the client 302 determines in step S607whether a MLB 54 is installed therein. If no MLB 54 is installedtherein, the client 302 uses the image transformation function of theother machine in step S610, and then, the process ends.

If a MLB 54 is installed therein, the client compares the performance(transformation speed, for example) of the MLB 54 installed therein andthe performance of the other machine in step S608. According to thepresent embodiment, it is assumed that the client compares thetransformation speed of the MLBs 54.

If the transformation speed of its own MLB 54 is equal to or greaterthan that of the MLB 54 of the other machine, the client uses its ownMLB 54, and then the process ends. However, if the transformation speedof its own MLB 54 is lower than that of the MLB 54 of the other machine,the client uses the MLB 54 of the other machine in step S610, and thenthe process ends.

FIG. 15 is a flowchart showing exemplary operations of a server 301 thathas received a request for transforming an image from a client 302. Instep S701, the server 301 determines whether the requesting client 302is permitted to access the MLB 54. If the requesting client 302 is notpermitted to access the MLB 54, the server 301 sets the response to therequest to “refused” in step S702, and then, the process ends. Thedetermination may be made based on the IP address and/or the password ofthe client 302, or based on the traffic rate of the PCI bus. Accordingto another embodiment, the server 301 may accept any request from theclient 302, but in such a case, the server 301 may give higher priorityto image transformation for itself.

If the requesting client 302 is permitted to access the MLB 54 installedin the server 301, in step S703, the server 301 sets a URL in which therequesting client 302 stores the image that needs to be transformed. Instep S704, the server 301 determines whether there is a current job (ajob that is to be performed by using the MLB 54) that is currently beingperformed or a reserved job that needs to be performed.

If there is not a current job or reserved jobs, the server 301 sets therequest result as “accepted” in step S706. If there is a current job ora reserved job, in step S705, the server 301 registers the request fromthe client 302 in a transformation request queue provided in the MLB 54.In step S706, the server 301 sets the request result as “accepted”, andthen the process ends.

FIG. 16 is a flowchart for explaining exemplary transformation of animage performed by the server 301 in the case in which a user of the MFP202 (server 301) uses the MLB 54 installed therein.

If the server 301 determines that an image needs to be transformed instep S801, the server 301 further determines whether the MLB 54 iscurrently transforming another image in step S802. If the MLB 54 is nottransforming an image, the process proceeds to step S806.

In step S802, if the server 301 determines that the MLB 54 istransforming another image, the server 301 determines in step S803whether the transformation of the other image is requested by anothermachine. If the server 301 determines that the transformation of theother image is requested by itself, instead of another machine, theserver 301 puts its own request for transforming an image in thetransformation request queue in step S804.

In step S803, if the server 301 determines that the transformation ofanother image is requested by another machine, the server 301 interruptsthe currently being performed transformation of another image in stepS805 so that its own transformation request is performed at priority.

In step S806, after interrupting the currently being performedtransformation of another image, the server 301 performs its owntransformation request and transforms the image. The server 301 waitsuntil the transformation of the image is completed in step S807. Inresponse to the completion, the server 301 determines whether its owntransformation request is in the transformation request queue in stepS808.

If any, the server 301 performs step S806 again. In step S808, if theserver 301 determines that its own transformation request is not in thetransformation request queue, the server 301 determines whether there isany interrupted request for transforming an image in step S809.

If there is no interrupted request, the server 301 returns to step S801.If there is an interrupted request, the server 301 processes theinterrupted request for the other machine. After completing the process,the server 301 returns to step S801.

FIG. 17 is a flowchart for explaining an exemplary charging process. Thecharging process shown in FIG. 17 starts with receipt of atransformation request from a client 302, and ends with charging to theclient 302. The server 301 receives a transformation request in stepS901, and performs the requested transformation in step S902. The server301 determines that the requested transformation has been completed bythe MLB 54 in step S903, then the server 301 transmits a charge requestto the client 302 in step S904. Then, the process ends. The chargerequest corresponds to the “ChargeReq” shown in FIG. 5.

As described above, the present invention provides an apparatus for, anda method of providing an image transformation service by transformingthe format of an image transmitted from another apparatus connected tothe network.

The preferred embodiments of the present invention are described above.The present invention is not limited to these embodiments, butvariations and modifications may be made without departing from thescope of the present invention.

This patent application is based on Japanese Priority Patent ApplicationNo. 2003-144573 filed on May 22, 2003, the entire contents of which arehereby incorporated by reference.

1. A method in an image transforming apparatus of transforming an imageformat of image data stored in an apparatus connected to the imagetransforming apparatus via a network, the method comprising the stepsof: receiving a request from the apparatus for format information;providing the apparatus with the format information in response to therequest for format information, the format information containing pluraldifferent image format transformation types that can be performed withinthe image transforming apparatus, each image format transformation typeindicating a transformation from a respective initial image format to adifferent respective final image format; receiving a request fortransforming the image format of the image data from the apparatus, saidrequest being sent from the apparatus based on the format information;acquiring the image data from the apparatus; transforming the imageformat of the image data acquired from the apparatus thereby to formformat-transformed image data; and providing the format-transformedimage data to the apparatus, wherein the format information provided tothe apparatus further contains information of a transformation speed atwhich the image format of the image data can be transformed within theimage transforming apparatus; wherein the step of acquiring the imagedata comprises: informing the apparatus of a first location in which theapparatus is to store the image data, the first location being indicatedas a URL; and acquiring the image data from the first location in whichthe apparatus has stored the image data.
 2. The method as claimed inclaim 1, wherein the step of providing the format-transformed image datacomprises the step of informing the apparatus of a second location inwhich the format-transformed image data are stored.
 3. The method asclaimed in claim 2, wherein the second location is indicated as a URL.4. The method as claimed in claim 1, wherein the image format of theimage data is transformed by hardware.
 5. The method as claimed in claim1, wherein the format information provided to the apparatus furthercontains information of a transformable range of magnification at whichthe image format of the image data can be transformed.
 6. The method asclaimed in claim 1, wherein a charge is made to the apparatus based onthe transformation of the image data.
 7. The method as claimed in claim1, wherein, in the step of providing the apparatus with the formatinformation, the format information provided to the apparatus depends ona kind of the apparatus.
 8. The method as claimed in claim 1, wherein,in the step of providing the apparatus with format information, if theapparatus is not authorized to receive the format information, theformat information is not provided to the apparatus.
 9. The method asclaimed in claim 1, wherein, in the step of transforming the imageformat of the image data, if a plurality of items of image data are tobe transformed, the transformation of the items of image data isprioritized.
 10. An image transforming apparatus, comprising: areceiving unit that receives a request for format information fromanother apparatus which is connected to the image transforming apparatusvia a network and which stores image data to be transformed; aninformation providing unit that provides the format information to theother apparatus in response to the request for format information, theformat information containing plural different image formattransformation types that can be performed within the image transformingapparatus, each image format transformation type indicating atransformation from a respective initial image format to a differentrespective final image format; an acquiring unit that acquires from theother apparatus the image data and a request for transforming the imageformat of the image data, said request being sent from the apparatusbased on the format information; a transforming unit that transforms theimage format of the image data acquired from the other apparatus intoformat-transformed image data; and a data providing unit that providesthe format-transformed image data to the other apparatus; wherein theinformation providing unit provides format information containinginformation of a transformation speed at which the image format of theimage data can be transformed within the image transforming apparatus,wherein the acquired unit provides a first location in which the otherapparatus is to store the image data to be transformed and acquires theimage data to be transformed that is stored in the first location by theother apparatus, the first location being indicated as a URL.
 11. Theimage transforming apparatus as claimed in claim 10, wherein the dataproviding unit provides the format-transformed image data to the otherapparatus by storing the format-transformed image data in a secondlocation and informing the other apparatus of the second location sothat the other apparatus can fetch the format-transformed image data.12. The image transforming apparatus as claimed in claim 11, wherein thesecond location is indicated as a URL.
 13. The image transformingapparatus as claimed in claim 10, wherein the transforming unitcomprises hardware that can transform the image format of the imagedata.
 14. The image transforming apparatus as claimed in claim 10,wherein the information providing unit provides format informationcontaining information of a transformable range of magnification atwhich the image transforming apparatus can transform image format. 15.The image transforming apparatus as claimed in claim 10, furthercomprising: a charging unit that charges the other apparatus based ontransformation of the image format.
 16. The image transforming apparatusas claimed in claim 10, wherein the information providing unit providesdifferent format information depending on a kind of the other apparatus.17. The image transforming apparatus as claimed in claim 10, wherein ifthe other apparatus is not authorized to receive the format information,the information providing unit does not provide the format informationthereto.
 18. The image transforming apparatus as claimed in claim 10,wherein the transforming unit performs a transformation requested by theimage transforming apparatus at priority over a transformation requestedby the other apparatus.
 19. The image transforming apparatus as claimedin claim 10, further comprising: hardware resources that are used forforming images; and computer programs that perform image processing. 20.A nontransitory computer readable recording medium encoded with computerexecutable instructions, which when executed by an image transformingapparatus, cause the image transforming apparatus to perform a method oftransforming an image format of image data stored in an apparatusconnected to the image transforming apparatus via a network, the methodcomprising: receiving a request from the apparatus for formatinformation; providing the apparatus with the format information inresponse to the request for format information, the format informationcontaining plural different image format transformation types that canbe performed within the image transforming apparatus, each image formattransformation type indicating a transformation from a respectiveinitial image format to a different respective final image format;receiving a request for transforming the image format of the image datafrom the apparatus, said request being sent from the apparatus based onthe format information; acquiring the image data from the apparatus;transforming the image format of the image data acquired from theapparatus thereby to form format-transformed image data; and providingthe format-transformed image data to the apparatus, wherein the formatinformation provided to the apparatus further contains information of atransformation speed at which the image format of the image data can betransformed within the image transforming apparatus; wherein the step ofacquiring the image data comprises: informing the apparatus of a firstlocation in which the apparatus is to store the image data, the firstlocation being indicated as a URL; and acquiring the image data from thefirst location in which the apparatus has stored the image data.
 21. Asystem comprising: an image transforming apparatus and a clientapparatus which is connected to the image transforming apparatus via anetwork and which stores image data to be transformed, the imagetransforming apparatus comprising: a receiving unit that receives arequest for format information from the client apparatus; an informationproviding unit that provides the format information to the clientapparatus in response to the request for format information, the formatinformation containing plural different image format transformationtypes that can be performed within the image transforming apparatus,each image format transformation type indicating a transformation from arespective initial image format to a different respective final imageformat, format information further containing information of atransformation speed at which the image format of the image data can betransformed within the image transforming apparatus; an acquiring unitthat acquires from the other client apparatus the image data and arequest for transforming the image format of the image data, saidrequest being sent from the client apparatus based on the formatinformation; a transforming unit that transforms the image format of theimage data acquired from the client apparatus into format-transformedimage data; and a data providing unit that provides theformat-transformed image data to the client apparatus; wherein theclient apparatus is configured to perform image transformation andcompares a transformation speed at which the image format of the imagedata can be transformed within the client apparatus with the informationof the transformation speed at which the image format of the image datacan be transformed within the image transforming apparatus, and when thetransformation speed of the client apparatus is lower than thetransformation speed of the image transformation apparatus, the clientapparatus requests the image transformation apparatus to transform theimage format of the image data, and when the transformation speed of theclient apparatus is equal to or greater than the transformation speed ofthe image transformation apparatus, the client apparatus transforms theimage format of the image data, wherein the acquiring unit provides afirst location in which the other apparatus is to store the image datato be transformed and acquires the image data to be transformed that isstored in the first location by the other apparatus, the first locationbeing indicated as a URL.